SSC JE Electrical 2018 with solution SET-1

An AC or DC generator requires direct current to energize its magnetic field. The DC field current is obtained from a separate source called an exciter. Either rotating or static-type exciters are used for AC power generation systems. There are two types of rotating exciters: brush and brushless. The primary difference between brush and brushless exciters is the method used to transfer DC exciting current to the generator fields. Static excitation for the generator fields is provided in several forms including field-flash voltage from storage batteries and voltage from a system of solid-state components. DC generators are either separately excited or self-excited.
EXCITATION SYSTEMS in current use include direct-connected or gear-connected shaft-driven DC generators, belt-driven or separate prime mover or motor-driven DC generators, and DC supplied through static rectifiers.
Static Excitation System
As the name indicates, all the components in this type of excitation system are static. A set of rectifiers is fed from a transformer that steps down the main generator or auxiliary bus voltage. The rectifiers supply the main generator excitation current directly through slip rings and they may be controlled or uncontrolled.
 
An external source of DC is necessary for the initial excitation of the field windings. On engine-driven generators, the initial excitation may be obtained from the storage batteries used to start the engine or from control voltage at the switchgear.
The main advantage of the static exciter is improved response as the field current is controlled directly by the thyristor rectifier but, of course, if the generator terminal voltage is depressed too low then excitation power will be lost. It is again possible to provide the power supply from both voltage and current transformers at the generator terminals but it is doubtful whether the improved response of the static exciter over a permanent magnet brushless scheme can be justified for many small embedded generators.
 

Let us now consider a p-n junction in which one side a p-type semiconductor and the other side is an n-type semiconductor. The P side has a higher concentration of holes while the n-side has a higher concentration of free electrons. As a result, there is a tendency of the holes in the P-side to diffuse to the N-sides and the electrons in the N side to diffuse to the P-side.
Formation of depletion region: The region on both the n- and P sides which are close to the junction develops a low concentration of charge carriers. This happens because, as the electrons on the N-side diffuse towards the p-side, they recombine with the holes close to the junction.
The same thing occurs with the hole diffusing from the p-side to the n-side. Since a large number of recombinations occur close to the junction, the charge carrier densities close to the junction decrease drastically. This region close to the junction is called the depletion region or depletion layer. 
Creation of junction potential: The electric neutrality of the semiconductor material is disturbed the region close to the junction because of the recombination which forms the depletion region. In the p-side of the depletion region, we have an accumulation of fixed negative charge ion since the atoms have acquired electrons from the n-region. Similarly, on the n-type side of the depletion region, there is an accumulation of fixed positive charge ions because the free electrons have moved to p-region.
This double layer of positive and negative charges produces an electric field which exerts a force on the electrons and holes against their diffusion. The potential difference corresponding to this electric field is called the potential barrier (or junction potential or barrier potential VB). This name implies that this potential difference acts as a barrier against the diffusion of electrons and holes from their majority side to the minority side. The magnitude of this potential barrier is about 0.3 V in case of germanium and about 0.7 V for silicon-based semiconductor diodes. The width of the depletion layer being of the order of one micron, the electric field that exists in the depletion layer is of the order of 105 Vm-1, which is indeed very high.
 

In DC machine the field resistance is low i.e the field resistance consist of less number of turns having the large cross-section area. While the resistance of shunt is high i.e the more number of turns and smaller cross-section area.
The resistance of the shunt field winding is large so that current in the winding is small compared to the rated armature current of the machine. To produce the necessary m m.f.. the winding consists of many turns.
The resistance of the series field winding is made as low as possible so that voltage drop across the winding is minimum. To produce the same flux at rated conditions, the turns of a series winding are fewer than those of a shunt winding since the series winding carries the rated current of the machine.
 

Energy consumption or power consumption refers to the electrical energy per unit time is given as
E = Power × Time = P × T
(i) 5 fans of 70 watts working 16 hours per day
Energy consumption = power × Time = 5 × 70 × 16 = 5600 watt-hr
(ii) One washing machine of 2000 watt operating for 1 hours
Energy consumption = 2000 × 1 = 2000 watt-hr
Energy consumption in the month of June i.e for 30 days
(Energy consumption of Fan + Energy consumption of Washing Machine) × 30
 (5600 + 2000) × 30 = 228000 watt-hr or 228 KWH
 

SCOTT CONNECTION
The Scott connection is used to convert three-phase power into two-phase power into two single-phase transformers. The Scott connection is very similar to the T connection that one transformer, called the main transformer, must have a center or 50% tap, and t second or teaser transformer must have an 86.6% tap on the primary side. The difference between the Scott and T connections lies in the connection of the secondary winding (Figure). In the Scott connection, the secondary windings of each transformer provide the phases of a two-phase system. The voltages of the secondary windings are 90° out of phase with each other. The Scott connection is generally used to provide two-phase power for the operation of two-phase motors.
 
 

The power triangle or Impedance triangle of the AC circuit is shown Below
Cosφ = Base ⁄ Hypotenuse = Active Power  ⁄ Apparent Power
Active Power = Apparent power × Cosφ
Sinφ = Perpendicular ⁄ Hypotenuse = Reactive Power  ⁄ Apparent Power
Reactive Power = Apparent power × Sinφ
or
Reactive Power = (Active Power × Sinφ) ⁄ Cosφ
cosφ = 0.8
Sin2φ = 1 − cos2φ
Sin2φ = 1 − (0.8)2
Sinφ = 0.6
Reactive Power =(40 × 0.6) ⁄ 0.8
Reactive Power = 30 VAR